Driving circuit for fluid jet head, driving method for fluid jet head, and fluid jet printing apparatus

ABSTRACT

An ejection head driving circuit that supplies a driving voltage waveform to an ejection head has ejection nozzles that cause fluid to be ejected. A target voltage waveform output unit outputs a target voltage waveform to the ejection head. Power source units generate electric power at different voltage values. Negative feedback control units supply electric power from the respective power source units to the ejection head and perform a negative feedback control of the voltage values so that the voltage value to be applied to the ejection head matches the target voltage waveform. A power source connecting unit selects one of the power source units on the basis of the voltage value applied to the ejection head or the voltage value of the target voltage waveform, connects the selected power source unit to the ejection head, and disconnects the remaining power source units from the ejection head.

This application claims priority to Japanese Patent Application No.2008-275231 filed on Oct. 27, 2008, and the entire disclosure thereof isincorporated herein by reference.

BACKGROUND

1. Technical Field

The present invention relates to a technique to discharge fluid from anejection head having minute ejection nozzles by supplying a drivingvoltage waveform to the ejection head.

2. Related Art

So-called an ink-jet printer is capable of printing a high-quality imageby discharging ink of an accurate amount to accurate positions fromminute ejection nozzles, and is nowadays widely used. It is alsoconsidered to be possible to manufacture various minute components suchas electrodes, sensors, or biochips by discharging various types offluid instead of ink toward a substrate using this technique.

In the technique as described above, a specific ejection head isemployed so as to enable discharge of fluid such as ink by an accurateamount at accurate positions. Although there are several methods asmethods of driving the ejection head, a method of deforming minute fluidchambers provided in the interior of the ejection head by actuators, andcausing the fluid in the fluid chambers to be discharged from theejection nozzles by using the capacity change of the fluid chambers atthat moment is known as a representative method. As the actuator, apiezoelectric element is widely used because it has a highresponsiveness and is able to generate strong force.

In order to print an image quickly while maintaining the quality, it isnecessary to discharge the ink at a high repetition frequency whilemaintaining the accuracy in the amount and the position of the ink to bedischarged. Therefore, employing a driving voltage waveform to beapplied to the actuator such as the piezoelectric element, which has atrapezoidal shape in which a rising portion and a lowering portion ofthe voltage are sloped, instead of a driving waveform having a simplerectangular waveform is contemplated (JP-A-7-178907).

However, when an attempt is made to apply the trapezoidal-shaped drivingwaveform in order to discharge the fluid of an accurate amount at thehigh repetition frequency, the following problems arise. In a step ofgenerating the driving voltage waveform to be applied, there is aproblem such that a large power loss occurs in order to generate avoltage waveform which changes in a sloped manner at the rising or thelowering portion of the waveform. When the actuator includes a capacitycomponent as in the case of the piezoelectric element, there is also aproblem such that a reactive power for charging and dischargingelectricity with respect to the capacity components of the actuator isconsumed on the side of the driving voltage waveform generating circuit,and hence the power efficiency is further lowered. Furthermore, sincethe dissipated power is transformed into heat, it is required to releaseheat from the driving voltage waveform generating circuit, resulting ina larger circuit.

SUMMARY

An advantage of some aspects of the invention is to provide an ejectionhead driving technique which achieves high power efficiency and enablesdownsizing of the apparatus.

According to a first aspect of the invention, an ejection head drivingcircuit configured to supply a driving voltage waveform to an ejectionhead provided with ejection nozzles for ejecting fluid includes

a target voltage waveform output unit configured to output a targetvoltage waveform to supply to the ejection head,

a plurality of power source units configured to generate electric powershaving different voltage values,

a plurality of negative feedback control units configured to supply theelectric powers from the respective power source units to the ejectionhead and perform a negative feedback control of the voltage values sothat the applied voltage value to the ejection head matches with thetarget voltage waveform, and

a power source connecting unit configured to connect one of the powersource units to connect to the ejection head based on the appliedvoltage value or the voltage value of the target voltage waveform, anddisconnect the other power source units from the ejection head.

According to a second aspect of the invention, a method of driving anejection head by supplying a driving voltage waveform to the ejectionhead provided with ejection nozzles to eject fluid includes

outputting a target voltage waveform to be supplied to the ejectionhead, the target voltage waveform including a voltage increasing portionin which a voltage value increases as time elapses, a voltagemaintaining portion in which the voltage value stays, and a voltagedecreasing portion in which the voltage value decreases as time elapses,

generating electric powers of different voltage values from a pluralityof power source units,

selecting one of the plurality of power source units on the basis of theapplied voltage value to the ejection head or the voltage value of thetarget voltage waveform and

performing a negative feedback control on the voltage value receivedfrom the selected power source unit so that the applied voltage value tothe ejection head matches with the target voltage waveform.

In the ejection head driving circuit and the method of driving anejection head according to the aspects of the invention, the targetvoltage waveform to be supplied to the ejection head is stored inadvance, and the target voltage waveform includes at least the voltageincrementing portion in which the voltage value is increased with theelapse of time, the voltage maintaining portion in which the voltagevalue is maintained, and the voltage decrementing portion in which thevoltage value is decreased with the elapse of time. Also, the pluralityof power source units which generate the electric powers having thevoltage values different from each other are provided, and the negativefeedback control units are provided for the respective power sourceunits, and the target voltage waveform is inputted to the respectivenegative feedback control unit.

Consequently, in the respective negative feedback control units, theelectric powers received from the respective power source units can besupplied to the ejection head while performing the negative feedbackcontrol according to the target voltage waveform. Then, one of theplurality of power source units (and the negative feedback controlunits) configured as described above is selected on the basis of thevoltage value applied to the ejection head or the voltage value of thetarget voltage waveform, and is connected to the ejection head, and theremaining power source units (and the negative feedback control units)are disconnected from the ejection head.

When a trapezoidal driving voltage waveform is applied to the ejectionhead for discharging the fluid of an adequate amount at a highrepetitive frequency, a large power loss occurs on the side of thecircuit which generates the driving voltage waveform and, in addition,the apparatus needs to be made larger as a result of the heat-releasingmeasure taken in association with the power loss. In contrast, bydriving the ejection head while switching among the plurality of powersource units which generate the electric powers having different voltagevalues, the potential difference between the voltage value generated bythe power source unit and the voltage value applied to the ejection headcan be made smaller, so that the power consumption when driving theejection head can be reduced.

Preferably, the power source units which are capable of storing electricpower from an external power source are used as the power source units,and the ejection head is driven as follows. The voltage value applied tothe ejection head or the voltage value of the target voltage waveform isdetected. Then a first power source unit which generates a voltage valuehigher than the detected voltage value and a second power source unitwhich generates a voltage value lower than the detected voltage areselected. The ejection head is driven by being connected to the firstpower source unit when the voltage value applied to the ejection head islower than the voltage value of the target voltage waveform or to thesecond power source unit when higher, and disconnecting the remainingpower source units from the ejection head.

In this configuration, when the voltage value applied to the ejectionhead is higher than the target voltage waveform, the voltage value canget close to the target voltage waveform quickly by having the electricpower applied to the ejection head collected by the power source unithaving a low output voltage value. In contrast, when the voltage valueapplied to the ejection head is lower than the target voltage waveform,the voltage value can get close to the target voltage waveform quicklyby having the electric power supplied from the power source unit havinga high output voltage value to the ejection head. Therefore, theejection head can be driven with an accurate driving voltage waveform.

In the ejection head driving circuit, preferably, the ejection head isdriven in the following manner. The power source unit which is able tostore electric power from an external power source is employed. Also, aload which is able to store electric power from an external power sourceis connected in parallel with the ejection head on the downstream of thepower source connecting unit when viewed from the power source unit.Then, when the power source unit to be connected to the ejection head isselected on the basis of the voltage value applied to the ejection heador the voltage value of the target voltage waveform, the selected powersource unit is connected to the ejection head and the load, and otherpower source units are disconnected from the ejection head and the load.

The plurality of ejection nozzles are provided on the ejection head, andthere may be cases where all, some or none of the ejection nozzles aredriven simultaneously. From this reason, the operating environment ofthe driving circuit which supplies the driving voltage waveform to theejection head fluctuates depending on the state of usage of the ejectionhead. In order to reduce the effect of the operating environment toenable a stable supply of the driving voltage waveform, it is necessaryto secure a sufficient reserve capacity in the driving circuit,resulting in complication or upsizing of the driving circuit. Incontrast, by connecting the load which is capable of storing theelectric power from an external power source parallel to the ejectionhead, even though the state of usage of the ejection head fluctuates,the operating environment of the driving circuit which supplies thedriving voltage waveform does not fluctuate significantly. Therefore, itis not necessary to secure the reserve capacity in the driving circuit,and hence the constantly stable driving voltage waveform can be suppliedwithout the complication or the upsizing of the driving circuit.

The capacity of the load connected in parallel to the ejection head maybe configured to be changeable according to the state of usage of theejection head. For example, it is also possible to increase the capacityof the load with decrease of the number of the ejection nozzles to bedriven or decrease the capacity of the load with increase of the numberof the ejection nozzles to be driven. In this manner, by changing thecapacity of the load so as to cancel the fluctuation of the loadcapacity of the ejection head, the fluctuation of the load for thedriving circuit can be reduced. Consequently, the ejection head can bedriven using the stable driving voltage waveform while downsizing thedriving circuit.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be described with reference to the accompanyingdrawings, wherein like numbers reference like elements.

FIG. 1 is an explanatory drawing showing a rough configuration of anejection head driving circuit according to an embodiment of theinvention.

FIG. 2 is an explanatory drawing illustrating a driving voltage waveformto be supplied to an ejection head.

FIG. 3 is an explanatory drawing illustrating a configuration of anejection head driving circuit according to a first embodiment in whichonly an effect of reducing an operational potential difference is used.

FIGS. 4A to 4C are explanatory drawings showing an operation of theejection head driving circuit according to the first embodiment whichdrives a load.

FIGS. 5A and 5B are explanatory drawings illustrating a comparativeejection head driving circuit which drives the load using a single powersource and a single negative feedback circuit.

FIGS. 6A and 6B are explanatory drawings showing reasons why powerconsumption is reduced by reducing an operational potential differencein the ejection head driving circuit according to the first embodiment.

FIG. 7 is an explanatory drawing illustrating the ejection head drivingcircuit which is able to apply a driving voltage whose voltage valueschange between positive values and negative values to the load.

FIG. 8 is an explanatory drawing illustrating a configuration of theejection head driving circuit according to a second embodiment whichperforms a power recovery in addition to the reduction of theoperational potential difference.

FIGS. 9A and 9B are explanatory drawings showing an operation of theejection head driving circuit according to the second embodiment whichdrives a capacitive load.

FIGS. 10A and 10B are explanatory drawings showing reasons why the powerconsumption is reduced by performing the power recovery in addition tothe reduction of the operational potential difference in the ejectionhead driving circuit according to the second embodiment.

FIGS. 11A to 11C are explanatory drawings showing a state of driving anejection head using an ejection head driving circuit according to afirst modified embodiment.

FIG. 12 is an explanatory drawing illustrating an example of theejection head driving circuit according to a second modified embodiment.

FIG. 13 is an explanatory drawing illustrating an example of theejection head driving circuit according to a third modified embodiment.

FIGS. 14A and 14B are explanatory drawings showing a state of drivingthe ejection head using an ejection head driving circuit according to afourth modified embodiment.

FIG. 15 is an explanatory drawing illustrating an example of theejection head driving circuit according to a fifth modified embodiment.

FIG. 16 is an explanatory drawing illustrating an example of theejection head driving circuit according to a sixth modified embodiment.

DESCRIPTION OF EXEMPLARY EMBODIMENTS

In the following description, in order to clarify contents of theinvention according to the present application described above,embodiments will be described in the following order.

A. Summary of Embodiments

B. First Embodiment (embodiment in which an effect of a reduction of anoperational potential difference is used)

B-1. Configuration of Ejection Head Driving Circuit

B-2. Operation of Ejection Head Driving Circuit

C. Second Embodiment (embodiment in which an effect of a reduction of anoperational potential difference and an electric power recovery is used)

C-1. Configuration of Ejection Head Driving Circuit

C-2. Operation of Ejection Head Driving Circuit

D. Modified Embodiments

D-1. First Modified Embodiment

D-2. Second Modified Embodiment

D-3. Third Modified Embodiment

D-4. Fourth Modified Embodiment

D-5. Fifth Modified Embodiment

D-6. Sixth Modified Embodiment

A. Summary of Embodiments

Embodiments of various modes are conceivable for an ejection headdriving circuit of the present invention, and the respective embodimentswill be described below. However, in view of better understanding,summary common to the respective embodiments will be described brieflyfirst.

FIG. 1 is an explanatory drawing conceptually showing a state of drivingan ejection head of an inkjet printer. As is known publicly, the inkjetprinter includes an ejection head 50 configured to discharge ink dropsmounted thereon. The ejection head 50 is connected to a scanning motor60 via a scanning belt 62. Then, an image can be printed on a printingmedium by driving the scanning motor 60 and causing the ejection head 50to discharge the ink drops while moving the ejection head 50 relativelywith respect to the printing medium (printing paper or the like).

FIG. 1 conceptually shows an internal configuration of the ejection head50 as well. As illustrated, the ejection head 50 includes a plurality ofejection nozzles configured to discharge the ink drops, and ink chambersfor the respective ejection nozzles. Also, piezoelectric elements, notshown, are provided for the respective ink chambers. When a voltage isapplied to the piezoelectric elements in a state in which ink issupplied to the ink chambers, the ink chambers are deformed by thepiezoelectric elements, so that the discharge of the ink in the inkchambers from the ejection nozzles is enabled according to a decrease inthe volume at that time.

As described above, a driving voltage waveform having a specificwaveform as described later is employed for the voltage to be applied tothe respective piezoelectric elements in order to enable the dischargeof the small ink drops at a high repetition frequency and in the samesize with stability. The driving voltage waveform is generated by anejection head driving circuit 100 described later, and is supplied tothe piezoelectric elements of the respective ejection nozzles viatransmission gates. A nozzle selecting circuit is connected to thetransmission gates, and when the transmission gates are set to an ONstate by the nozzle selecting circuit, the driving voltage waveform fromthe ejection head driving circuit 100 passes through the transmissiongates and is supplied to the piezoelectric elements.

So-called a printer driver is connected to the nozzle selecting circuit.The printer driver, upon reception of image data of an image to beprinted, determines at which pixels ink dots are to be formed byapplying various kinds of image processing to the image data. Then,after having generated nozzle selecting data on the basis of the resultof determination, the generated nozzle selecting data is outputted tothe nozzle selecting circuit. The nozzle selecting circuit switches thetransmission gates to the ON state or an OFF state according to thereceived nozzle selecting data. Consequently, only the ejection nozzlesof the transmission gates set to the ON state are driven and eject theink drops, so that the image on a printing medium is printed.

FIG. 2 is an explanatory drawing illustrating the driving voltagewaveform for driving the ejection nozzles. In the illustrated drivingvoltage waveform, one each of ink drop that is, two ink drops in totalcan be discharged in a front half and a rear half of the waveform.Therefore, one ink drop is discharged when supplying only the front halfor the rear half of the waveform to the piezoelectric elements throughthe transmission gates, and two ink drops are discharged when supplyingthe entire waveform to the piezoelectric elements therethrough. Then,when one ink drop is discharged, a small ink dot is formed on theprinting medium, and when two ink drops are discharged, a large ink dotis formed. In this manner, ink dots having different sizes can beformed.

The driving voltage waveform includes, in detail, a voltage incrementingportion in which a voltage value is increased little by little withelapse of time, a voltage maintaining portion in which the voltage valueis maintained at a constant value, and a voltage decrementing portion inwhich the voltage is decreased little by little with the elapse of time.The driving voltage waveform is not limited to the one including theseportions only, but may include a portion where the voltage value changesin a staircase pattern, or may be a curved waveform. Here, in thevoltage incrementing portion, the voltage value to be applied to theejection head 50 is gradually increased, and a positive electric currentflows to the ejection head 50. This means that an electric power issupplied (charged) to the ejection head 50. An electric powercorresponding to the product of a potential difference between thevoltage of a power source which supplies the electric power and thevoltage of the ejection head 50 (hereinafter, this potential differenceis referred to as “operational potential difference” in thisspecification), and a current value which flows into the ejection head50 is consumed in the ejection head driving circuit 100.

In contrast, in the voltage decrementing portion, the voltage value tobe applied to the ejection head 50 is gradually decreased, and anegative electric current flows to the ejection head 50. This means thatthe electric power is thrown away (discharged) from the ejection head50. At this time as well, an electric power corresponding to the productof an operational potential difference between the power source and theejection head 50 and the current value which flows from the ejectionhead 50 is consumed in the ejection head driving circuit 100. Therefore,when an attempt is made to generate a driving voltage waveform having alarge operational potential difference between the power source and theejection head 50, a large electric power is consumed on the side of thedriving circuit. Therefore, it is desired to generate a driving waveformwith high efficiency as much as possible.

Since the piezoelectric elements mounted on the ejection head 50 areso-called a capacitive load, the electric power supplied in the voltageincrementing portion is stored on the side of the ejection head 50.Therefore, if it is possible to recover the electric power to be wastedin the ejection head 50 in the voltage decrementing portion to supply tothe ejection head 50 to use for increasing the voltage value, a powerloss would be reduced significantly. In view of such circumstances, thefollowing configuration is employed in the ejection head driving circuit100 in the embodiment shown in FIG. 1.

In other words, the ejection head driving circuit 100 in the embodimentshown in FIG. 1 includes a plurality of power source units 10 whichgenerate the electric power to be supplied to the ejection head 50, andthe each power source unit 10 is provided with a negative feedbackcontrol unit 30. Also, the ejection head driving circuit 100 includes atarget voltage waveform output unit 20 configured to output a targetvoltage waveform to be applied to the ejection head 50. Then, thenegative feedback control units 30 provided for the respective powersource units 10, upon reception of the target voltage waveform from thetarget voltage waveform output unit 20, each supplies the electric powergenerated at the power source unit 10 to the ejection head 50 whileperforming a negative feedback control so that the voltage value to beapplied to the ejection head 50 matches the target voltage waveform. Inother words, each pair of the power source unit 10 and the negativefeedback control unit 30 corresponding thereto constitutes, so to say, asmall driving circuit.

Then, by supplying the target voltage waveform from the target voltagewaveform output unit 20 for the respective driving circuits, the drivingof the ejection head 50 is enabled. In FIG. 1, each pair of the powersource unit 10 and the corresponding negative feedback control unit 30are surrounded by a rectangle of a fine dashed line to indicate thateach constitutes the small driving circuit. Also, the plurality of powersource units 10 generate electric powers having voltage values differentfrom each other. In the illustrated example, the four power source units10 are provided, and the voltage values generated by the respectivepower source units 10 are E1, E2, E3, and E4 (E1<E2<E3<E4). The numberof the power source units 10 is not limited to four, and may be anarbitrary number as long as it is two or larger as a matter of course.

A power source connecting unit 40 selects the one power source unit 10from among the plurality of power source units 10 (therefore, the drivecircuit including the selected power source unit 10) on the basis of thevoltage value applied to the ejection head 50 or the voltage value ofthe target voltage waveform outputted from the target voltage waveformoutput unit 20. For example, when the voltage value to be applied to theejection head 50 is low, the driving circuit including the power sourceunit 10 having a low voltage value is selected. In the exampleillustrated in FIG. 1, the driving circuit indicated as “a” or thedriving circuit indicated as “b” is selected. When the voltage value tobe applied is high, the driving circuit including the power source unit10 having a high voltage value (in the example in FIG. 1, the drivingcircuit indicated as “c” or “d”) is selected and, when an intermediatevoltage value is applied, the driving circuit including the power sourceunit 10 having an intermediate voltage value (the driving circuitindicated as “b” or “c” in the example in FIG. 1) is selected.

Then, the power source connecting unit 40 connects the selected drivingcircuit (that is, the power source unit 10 and the negative feedbackcontrol unit 30) to the ejection head 50, and other driving circuits aredisconnected from the ejection head 50. Then, the negative feedbackcontrol unit 30 of the driving circuit connected to the ejection head 50drives the ejection head 50 using the electric power from the powersource unit 10 while performing the negative feedback control accordingto the target voltage waveform supplied from the target voltage waveformoutput unit 20. In this configuration, the above-described “operationalpotential difference” can be maintained to a small value, and hencepower consumption when generating the driving voltage waveform as shownin FIG. 2 can be reduced.

In a state in which the voltage value of the target voltage waveform iscontrolled to be gradually lowered, the electric powers stored in therespective piezoelectric elements of the ejection head 50 are recoveredto the power source units 10. The electric powers recovered from theejection head 50 can be used again when increasing the voltage value ofthe target voltage waveform again.

In this manner, the ejection head driving circuit 100 in this embodimentincludes the plurality of power source units 10 generating differentvoltage values and the negative feedback control units 30 correspondingto the respective power source units 10. Then, by driving the ejectionhead 50 while switching the power source units 10 and the negativefeedback control units 30 according to the voltage value to be appliedto the ejection head 50, the driving voltage waveform is supplied to theejection head 50 while maintaining the operational potential differenceto a small value. Therefore, the power consumption can be reduced. Also,in a state in which a target voltage to be applied to the ejection head50 is controlled to be lowered, the electric power stored on the side ofthe ejection head 50 is recovered to the power source units 10 and canbe reused for increasing the target voltage again, so that the powerconsumption as a whole can be dramatically reduced.

As described above, the number of the power source units 10 may be thearbitrary number of at least two. However, the larger the number of thepower source units 10 is the smaller the voltage difference between thevoltage value generated by the power source unit 10 and the voltagevalue applied to the ejection head 50 can be made, and hence thereduction of the power consumption is enabled.

In the example illustrated in FIG. 1, the power source connecting unit40 is provided between the negative feedback control units 30 and theejection head 50. However, FIG. 1 does not show a detailed configurationof the ejection head driving circuit 100, but only shows functionsincluded in the ejection head driving circuit 100 conceptually. Then, asdescribed above, the function of the power source connecting unit 40 isto connect and disconnect the small driving circuits including the powersource units 10 and the negative feedback control units 30 to and fromthe ejection head 50 according to the voltage value to be applied.Therefore, when such the function can be realized, it is not necessarilyrequired to provide the power source connecting unit 40 between thenegative feedback control unit 30 and the ejection head 50 and, forexample, it is also possible to provide the power source connecting unit40 between the power source unit 10 and the negative feedback controlunit 30.

The above description is also applicable to the power source units 10and the negative feedback control units 30. For example, a case in whichthe respective power source units 10 are connected in series is shown inFIG. 1. However, the respective power source units 10 may be providedseparately as long as the electric powers having the different voltagevalues can be generated. Also, as regards the negative feedback controlunit 30, the respective negative feedback control units 30 do not haveto be independent completely as shown in FIG. 1, and a configuration inwhich part of them are commonly used is also applicable.

The ejection head driving circuit 100 in the embodiment as describedabove will be described in detail below. As described above, with theejection head driving circuit 100 according to the embodiment, theejection head 50 can be driven efficiently while reducing the powerconsumption dramatically by using two effects when classified broadly,that is, an effect to reduce the power consumption by maintaining theoperational potential difference to a small value by switching the powersource units 10, and an effect to reduce the power consumption byrecovering the electric power stored in the ejection head 50. Therefore,for better understanding, a simplified ejection head driving circuit 100in which only the effect achieved by the operational potentialdifference reduction will be described first. Then, on the basis of thedescription, the ejection head driving circuit 100 in which both theeffect achieved by the operational potential difference reduction andthe effect achieved by the power recovery are utilized will bedescribed.

B. First Embodiment Embodiment in which an Effect of an OperationalPotential Difference Reduction B-1. Configuration of Ejection HeadDriving Circuit

FIG. 3 is an explanatory drawing illustrating the configuration of theejection head driving circuit according to a first embodiment. In theillustrated example, four power sources E1 to E4 are provided, and theelectric powers generated by the respective power sources E1 to E4 areconnected to the ejection head 50 via unipolar-type NMOS transistorsNtr1 to Ntr4. The first embodiment is based on the assumption of thecase in which the ejection head 50 is a resistive load, and the ejectionhead driving circuit 100 in the first embodiment reduces the powerconsumption using only the effect achieved by the reduction of theoperational potential difference and does not use the effect achieved bythe power recovery from the ejection head 50. In such a case, any typesof the power sources may be used as the power sources E1 to E4 such asprimary batteries, secondary batteries, mere capacitors, or so-calledpower source circuits as long as they can generate the voltage valuesdifferent from each other. Also, the transistors Ntr1 to Ntr4 are notlimited to the unipolar-type transistor, and transistors of othersystems such as a bipolar type may also be used.

In FIG. 3, the reason why diodes are inserted between the respectivetransistors Ntr1 to Ntr4 and the ejection head 50 is because theunipolar-type transistor used in this embodiment has a structure of ahigh-power driving vertical transistor, which may cause a reverse flowof electric current because a parasitic diodes are formed between drainsand sources and hence prevention of such reverse flow is wanted. In thecase of FIG. 3, the parasitic diodes are integrated in such a mannerthat the load side is directed toward an anode and the power source sideis directed toward a cathode, although not shown. Therefore, when thevoltage of the load is increased to a level higher than the voltages ofthe power sources (E1-E4), the parasitic diodes of the transistors arebiased forward, and hence the electric current flows reversely from theload to the power sources via the parasitic diodes even though thetransistors are turned OFF. Therefore, the diodes are inserted in thedirection to block this reverse flow. When the transistors which do notcause the reverse flow of the electric current (ex. Bipolar type) areused, the diodes are not necessary.

An output terminal of an operational amplifier Opamp is connected togate electrodes of the respective transistors Ntr1 to Ntr4. In therespective transistors Ntr1 to Ntr4, the gate electrodes are appliedwith a pull-down process for avoiding erroneous operation. However, inorder to avoid complication of drawing, it is not shown in the drawing.As publicly known, when a NMOS-type transistor is configured in such amanner that a positive voltage is applied between the gate electrodesand source electrodes, a passage referred to as a channel for the charge(electron in this case) is formed. The higher the voltage value to beapplied between the gate-source electrodes, the easier the passage ofthe charge therethrough (equivalent value of resistant becomes smaller)because a large channel is formed. In contrast, the lower the voltagevalue to be applied between the gate-source electrodes, the moredifficult the passage of the charge, so that the equivalent value ofresistance is increased.

As the transistors Ntr1 to Ntr4, PMOS-type transistor may be employedinstead of the NMOS-type transistor. As shown in FIG. 3, when employingthe NMOS-type transistor, it is arranged in such a manner that a drainelectrode is connected to the side of the power sources (E1 to E4),while the source electrode is connected to the side of the ejection head50. In contrast, when employing the PMOS-type transistor, it is arrangedin such a manner that the source electrode is connected to the side ofthe power sources (E1 to E4), while the drain electrode is connected tothe side of the ejection head 50. In the case of the PMOS-typetransistor, a control is performed by applying a negative voltagebetween the gate electrode and the source electrode.

Two input terminals are provided on the operational amplifier Opamp. Ananalogue voltage outputted from a DA converter (hereinafter, referred toas DAC) is connected to one of the input terminals, and a voltageapplied to the ejection head 50 is connected to the other input terminalvia an input resistance Rs. Then, the output from the operationalamplifier Opamp is returned to the input terminal via a feedbackresistance Rf, and so-called a negative feedback circuit is formed.

For example, assuming that the voltage value applied to the ejectionhead 50 is lower than the analogue voltage outputted from the DAC, theoutput from the operational amplifier Opamp is increased and hence thevoltage applied to the gate electrodes is increased, so that theequivalent value of resistance of the transistors is decreased.Consequently, since the amount of voltage drop in the transistorsbecomes small, the voltage value applied to the ejection head 50 isincreased. In contrast, when the voltage value applied to the ejectionhead 50 is higher than the analogue voltage outputted from the DAC, theoutput from the operational amplifier Opamp is decreased, and hence thevoltage applied to the gate electrodes is decreased, so that theequivalent value of resistance of the transistors is increased.Consequently, since the amount of voltage drop in the transistorsbecomes large, the voltage value applied to the ejection head 50 isdecreased. Therefore, the voltage value applied to the ejection head 50can be changed according to the analogue voltage outputted from the DAC.

As described above, in the ejection head driving circuit 100 shown inFIG. 3, the respective transistors Ntr1 to Ntr4 and the operationalamplifier Opamp are combined to perform a negative feedback control ofthe voltage value applied to the ejection head 50. Therefore, thenegative feedback circuit configured by the respective transistors Ntr1to Ntr4 and the operational amplifier Opamp corresponds to the negativefeedback control unit 30 in FIG. 1. Also, the DAC which outputs theanalogue voltage to the operational amplifier Opamp corresponds to thetarget voltage waveform output unit 20 in FIG. 1. When the ejection head50 and the input resistance Rs are directly connected, a buffer circuitBuffer inserted between the ejection head 50 and the operationalamplifier Opamp is a circuit inserted to prevent the ejection head 50from being influenced by a direct connection between the ejection head50 and the input resistance Rs. Therefore, when the effect can beignored, the buffer circuit Buffer can be omitted, for example, if theresistance of the ejection head 50 is sufficiently smaller than theinput resistance Rs.

The output from the operational amplifier Opamp is connected to the gateelectrodes of the respective transistors Ntr1 to Ntr4 via switches SN1to SN4, and the switches SN1 to SN4 are controlled by a gate selectorcircuit 140. The gate selector circuit 140 has a function to detect theanalogue voltage outputted from the DAC or the voltage value applied tothe ejection head 50 (the output voltage of the operational amplifierOpamp depending on the cases), connect one of the switches SN1 to SN4,and disconnect other switches. As described above, since the pull-downprocess is applied to the respective gate electrodes of the transistorsNtr1 to Ntr4, if the switch is disconnected, the voltage is not appliedto the gate electrode of the transistor corresponding to thedisconnected switch. Consequently, the channel in the transistor isdisappeared and the electric current does not flow, so that the powersource on the upstream side of the transistor is electricallydisconnected from the ejection head 50.

In this manner, in the ejection head driving circuit 100 shown in FIG.3, when the gate selector circuit 140 connects the switches SN1 to SN4,the power sources E1 to E4 are connected to the ejection head 50 and, incontrast, when the gate selector circuit 140 disconnects the switchesSN1 to SN4, the power sources E1 to E4 are disconnected from theejection head 50. Therefore, the gate selector circuit 140 and theswitches SN1 to SN4 correspond to the power source connecting unit 40 inFIG. 1.

B-2. Operation of Ejection Head Driving Circuit

FIGS. 4A to 4C are explanatory drawings showing an operation of theejection head driving circuit 100 according to the first embodimentwhich drives the ejection head 50. For the sake of the convenience ofdescription, it is assumed that the power source E1 generates anelectric power having a voltage value E1, the power source E2 generatesan electric power having a voltage value E2, the power source E3generates an electric power having a voltage value E3, and the powersource E4 generates an electric power having a voltage value E4. Therespective voltage values have a relationship as; E1<E2<E3<E4.

Now, a case where the analogue voltage outputted from the DAC increasesfrom 0 (V) will be considered. As described in conjunction with FIG. 3,the analogue voltage outputted from the DAC is a target voltage to beapplied to the ejection head 50. When the target voltage to be appliedto the ejection head 50 is near 0 (V), the gate selector circuit 140connects (turns ON) the switch SN1 and disconnects (turns OFF) otherswitches SN2 to SN4. Consequently, the power source E1 having a smallestvoltage value from among the power sources E1 to E4 is connected to theejection head 50, and the negative feedback circuit is formed by thetransistor Ntr1 and the operational amplifier Opamp, whereby thenegative feedback control is performed so that the voltage value appliedto the ejection head 50 matches the output from the DAC. In FIG. 4A, astate in which the negative feedback circuit is formed by the transistorNtr1 and the operational amplifier Opamp is shown by a thick solid line.Consequently, the electric power of the power source E1 is applied tothe ejection head 50 via the transistor Ntr1 and the diode.

Here, the equivalent value of resistance of the transistor Ntr1 can bedecreased by increasing the voltage to be applied to the gate electrode,and the voltage value to be applied to the ejection head 50 can beincreased as the equivalent value of resistance is decreased. However,it cannot be increased to a voltage value generated by the power sourceE1 (that is, E1) or higher as a matter of course. Also, strictlyspeaking, the equivalent value of resistance of the transistor Ntr1cannot be decreased to zero and, the diode also has a certainresistance. Therefore, the voltage value applied to the ejection head 50can be increased only to a voltage value lower than the voltage valuegenerated by the power source E1 by an amount of voltage drop occurringin the transistor Ntr1 or the diode.

In this manner, the voltage value which can be applied to the ejectionhead 50 by the negative feedback circuit indicated by the thick solidline in FIG. 4A has an upper limit value. Therefore, when the voltagevalue outputted from the DAC (or the voltage value applied to theejection head 50) becomes higher than the upper limit value, the gateselector circuit 140 detects it, and disconnects (turns OFF) the switchSN1 and connects the switch SN2 (turns ON). Consequently, the negativefeedback circuit formed by the transistor Ntr1 and the operationalamplifier Opamp (the circuit indicated by the thick solid line in FIG.4A) is switched to a new negative feedback circuit formed by thetransistor Ntr2 and the operational amplifier Opamp (circuit indicatedby a thick broken line in FIG. 4A) and, in association with this, thepower source which supplies an electric power to the ejection head 50 isswitched from the power source E1 to the power source E2. As describedabove, since the power source E2 generates the electric power having avoltage value higher than the power source E1, with the configuration toswitch the power source as described above, even though the voltagevalue outputted from the DAC is further increased, the voltage value tobe applied to the ejection head 50 can be increased correspondingly.

As a matter of course, the voltage value which can be applied to theejection head 50 by the power source E2 also has an upper limit value.However, when the voltage value outputted from the DAC (or the voltagevalue applied to the ejection head 50) reaches its upper limit, then theelectric power may be supplied to the ejection head 50 using the powersource E3 by turning the switch SN2 OFF and turning the switch SN3 ON.

FIG. 4B shows a state in which the voltage is applied to the ejectionhead 50 while switching the negative feedback circuits and the powersources according to the voltage value to be applied. FIG. 4C shows astate of turning the switch SN1 and the switch SN2 ON and OFF forswitching the negative feedback circuits and the power sources. As shownin FIG. 4B and FIG. 4C, the electric power generated by the power sourceE1 is supplied to the ejection head 50 using the negative feedbackcircuit shown by the thick solid line in FIG. 4A by turning the switchSN1 ON and switch SN2 OFF until the voltage (driving voltage) to beapplied to the ejection head 50 raises from 0(V) and reaches E1.Strictly speaking, since a certain voltage drop occurs in thetransistors Ntr1 to Ntr4 or the diodes, only voltages not exceeding thevoltage value E1 generated by the power source E1 can be applied to theejection head 50. However, in order to avoid complicated description,the voltage drop occurring in the transistors Ntr1 to Ntr4 or the diodesis considered to be ignorable.

When the voltage (driving voltage) to be applied to the ejection head 50exceeds the voltage value E1, the electric power from the power sourceE2 is supplied to the ejection head 50 using the negative feedbackcircuit shown by the thick broken line in FIG. 4A. As shown in FIG. 4C,by switching the switch SN1 from ON to OFF and the switch SN2 from OFFto ON, the electric power from the power source E2 can be supplied tothe ejection head 50 using the negative feedback circuit shown by thethick broken line in FIG. 4A. In order to decrease the voltage to beapplied to the ejection head 50 from this state, the operation toincrease the voltage may be performed in the reverse order.

First of all, the voltage value outputted from the DAC is decreasedwhile keeping the state of the switches SN1 to SN4 as is. Then, theoutput from the operational amplifier Opamp is decreased, and thevoltage applied to the gate electrode of the transistor Ntr2 is lowered,so that the equivalent value of resistance of the transistor isincreased. Since the ejection head 50 is assumed to be the resistiveload, if the equivalent value of resistance of the transistor isincreased, the voltage value to be applied to the ejection head 50 islowered. Then, when the voltage value to be applied is decreased to thevoltage value E1, as shown in FIG. 4C, the negative feedback circuit isswitched from the circuit indicated by the thick broken line to thecircuit indicated by the thick solid line in FIG. 4A by switching theswitch SN2 to OFF and the switch SN1 to ON. After having switched thenegative feedback circuit in this manner, the voltage value to beapplied to the ejection head 50 can be decreased as the equivalent valueof resistance of the transistor Ntr1 included in the new circuit isincreased.

In this manner, in the ejection head driving circuit 100 in the firstembodiment, the voltage range which can be applied to the ejection head50 is divided into four voltage ranges of 0 (V) to E1, E1 to E2, E2 toE3, and E3 to E4, and the power sources and the negative feedbackcircuits are set in advance for the respective voltage ranges. Then,when the driving voltage to be applied to the ejection head 50 isincluded in any voltage range, the ejection head 50 is driven using thepower source and the negative feedback circuit corresponding to thevoltage range. However, when the driving voltage of the ejection head 50straddles over a plurality of voltage ranges, the power source and thenegative feedback circuit are switched, and the ejection head 50 isdriven using the power source and the negative feedback circuitcorresponding to a new voltage range. Consequently, the operationalpotential difference (the voltage difference between the output voltageof the power source which supplies the electric power and the voltage ofthe ejection head 50) is reduced and the electric power consumed whendriving the ejection head 50 can be reduced. This point will bedescribed as a postscript below.

FIGS. 5A and 5B are explanatory drawings illustrating an ejection headdriving circuit which drives the ejection head 50 using a single powersource and a single negative feedback circuit for comparison. FIG. 5Ashows a detailed circuit configuration and FIG. 5B shows a state inwhich the driving voltage of the ejection head 50 is raised from 0(V) tothe voltage value E4, and then is lowered to 0(V) again. In this manner,if the voltage is applied to the ejection head 50 within the range from0 (V) to E4, it is necessary to use the power source which generatesvoltage values of at least E4. When the resistance of the transistor Ntror the diode is considered, the voltage value generated by the powersource should be higher than E4. However, for easy understanding, theresistances of the transistor Ntr and the diode are considered to beignorable.

The power source E4 constantly generates a electric power having thevoltage value E4. Therefore, in the driving circuit shown in FIG. 5A,the voltage value E4 is constantly applied to the upstream side of thetransistor Ntr irrespective of the voltage value of the driving voltageto be applied to the ejection head 50. Then, when lowering the voltagevalue E4 to a driving voltage to be applied to the ejection head 50, theelectric power is consumed in the transistor Ntr. The amount of thispower consumption increases with increase voltage difference in theoperation of the transistor Ntr (that is, the voltage difference betweenthe upstream side and the downstream side of the transistor Ntr(operational potential difference)). Consequently, in the drivingcircuit shown in FIG. 5A, when the driving voltage to be applied to theejection head 50 is low, a significantly large amount of electric poweris consumed.

In contrast, in the ejection head driving circuit 100 in the firstembodiment shown in FIG. 3, the four power sources E1 to E4 generatingvoltages of different values and the negative feedback circuitscorresponding to the respective power sources are provided. As describedabove using FIG. 4A to FIG. 4C, the ejection head 50 is driven whileswitching the power sources E1 to E4 and the negative feedback circuitsdepending on which voltage range the driving voltage to be applied tothe ejection head 50 exists in among the ranges 0 (V) to E1, E1 to E2,E2 to E3, and E3 to E4.

FIGS. 6A and 6B show a state of driving the ejection head 50 whileswitching the power sources E1 to E4 in the ejection head drivingcircuit 100 in the first embodiment. Therefore, when the driving voltageto be applied to the ejection head 50 is within the voltage range of 0(V) to E1 for example, the electric power is supplied from the powersource E1, so that only the voltage value E1 is applied to thetransistor Ntr1. Also, even when the driving voltage to be applied tothe ejection head 50 rises to the voltage range of E1 to E2, only thevoltage value E2 is applied to the transistor Ntr2 because the powersource which supplies the electric power is switched to the power sourceE2.

Even when the driving voltage of the ejection head 50 further rises, thepotential difference in operation of the transistors Ntr1 to Ntr4(operational potential difference) can be reduced to voltage differencesof ranges like 0 (V) to E1, E1 to E2, E2 to E3, and E3 to E4 at the mostat last by switching the power source to supply the electric power tothe ejection head 50 to the power sources E3, E4. Consequently, as shownin FIG. 5A, the power consumption can be reduced significantly incomparison with the ejection head driving circuit in the related artwhich drives the ejection head 50 using the single power source and thesingle negative feedback circuit.

In the description given above, the driving voltage to be applied to theejection head 50 has been described to take voltage values from 0 (V) topositive values. However, by using a power source which generatesnegative voltage values, application of the driving voltage taking thenegative values is enabled. When the power source which generates thenegative voltage values and the power source which generates thepositive voltage values are used, the driving voltage whose voltagevalues change between positive values and the negative values can beapplied to the ejection head 50.

FIG. 7 is an explanatory drawing illustrating the ejection head drivingcircuit 100 which is able to apply the driving voltage whose voltagevalues change between the positive values and the negative values to theejection head 50. In the illustrated example, four power sources ofpower sources E5 to E8 generate electric powers having the positivevoltage values as in the case of the ejection head driving circuit 100shown in FIG. 3 and, in contrast, the four power sources of the powersources E1 to E4 generate electric powers having the negative voltagevalues. Correspondingly, as regards the four power sources of the powersources E5 to E8, the drain electrodes of respective NMOS-typetransistors (Ntr5 to Ntr8) are connected to the power sources (E5 to E8)and the source electrodes of the respective transistors (Ntr5 to Ntr8)are connected to the side of the ejection head 50 as in FIG. 3.

In contrast, as regards the four power sources of the power sources E1to E4, the drain electrodes of respective PMOS-type transistors (Ptr1 toPtr4) are connected to the power sources (E1 to E4) and the sourceelectrodes of the respective transistors (Ptr1 to Ptr4) are connected tothe side of the ejection head 50. Also, as regards the PMOS-typetransistors (Ptr1 to Ptr4), diodes for preventing the reverse flow areinserted between the transistors and the ejection head 50 in theopposite direction from the NMOS-type transistors (Ntr5 to Ntr8) (sothat the direction from the drain electrodes of the transistors Ptr1 toPtr4 toward the ejection head 50 correspond to the forward direction).

Then, assuming that the relationship of the magnitudes of the voltagevalues E1 to E8 generated by these power sources isE1<E2<E3<E4<0<E5<E6<E7<E8, if the driving voltage to be applied to theejection head 50 is a positive voltage value, the driving voltages of 0(V) to E8 (positive voltage values) can be applied to the ejection head50 by switching the switch to be turned ON from the switch SN5 to theswitch SN8 as the increase of the voltage value. Also, if the drivingvoltage to be applied is a negative voltage value, the driving voltagesof E1 (negative voltage values) to 0 (V) can be applied to the ejectionhead 50 by switching the switch to be turned ON from the switch SN4 tothe switch SN1 as the decrease of the voltage value (as the increase ofthe absolute value).

In the first embodiment described above, the ejection head 50 is assumedto be the resistive load, and hence the ejection head driving circuit100 in which only the effect to reduce the power consumption is used byreducing the operational potential difference by switching the pluralityof power source units 10 has been described. However, as describedabove, the piezoelectric elements mounted on the ejection head 50 aregenerally capacitive loads, and the supplied electric power is stored inthe ejection head 50. The term “capacitive load” means a load having afeature to store at least part of the supplied electric power.Therefore, if the electric power can be recovered from the ejection head50 and can be used again, the power consumption can further be reduced.In the actual ejection head driving circuit 100, the power consumptioncan significantly be reduced using the two effects; the effect achievedby the operational potential difference reduction described as the firstembodiment, and the effect achieved by the power recovery. An ejectionhead driving circuit 100 in a second embodiment configured as describedabove will be described below.

C. Second Embodiment Embodiment in which an Effect of an OperationalPotential Difference Reduction and an Electric Power Recovery C-1:Configuration of Ejection Head Driving Circuit

FIG. 8 is an explanatory drawing illustrating the configuration of theejection head driving circuit 100 according to the second embodiment. Inthe ejection head driving circuit 100 according to the secondembodiment, the four power sources E1 to E4 are provided in the samemanner as the ejection head driving circuit 100 according to the firstembodiment shown in FIG. 3, and generate the electric powers having thevoltage values E1, E2, E3, and E4, respectively. Also, the electricpowers from the respective power sources E1 to E4 are connected to theejection head 50 via the unipolar type NMOS transistors Ntr1 to Ntr4. Inthe second embodiment, since the electric power stored in the ejectionhead 50 needs to be recovered and reused, power sources which can storeat least part of the electric power supplied from the outside, such asthe secondary batteries or capacitors, are used as the power sources E1to E4.

Also, as shown in FIG. 8, the ejection head driving circuit 100according to the second embodiment is provided with unipolar type PMOStransistors Ptr0 to Ptr3 in a direction to feedback the electric powerfrom the ejection head 50 to the ground or the respective power sources;the power sources E1 to E3 in contrast to the ejection head drivingcircuit 100 according to the first embodiment shown in FIG. 3. Also, thetransistors Ptr0 to Ptr3 are not limited to the unipolar typetransistor, and transistors of other systems such as a bipolar type mayalso be used. Although the diodes for preventing the reverse flow areinserted between the transistors Ptr0 to Ptr3 and the ejection head 50as well, when the transistor having the structure which does not causethe reverse flow (ex. bipolar type) is used, these diodes are notnecessary.

The output terminal of the operational amplifier Opamp is connected tothe respective gate electrodes of the respective transistors Ntr1 toNtr4 on the side where the electric powers of the power sources E1 to E4are supplied to the ejection head 50 via the switches SN1 to SN4. Thisconfiguration is the same as that of the ejection head driving circuit100 according to the first embodiment shown in FIG. 3. However, asdescribed above, in the ejection head driving circuit 100 according tothe second embodiment, the transistors Ptr0 to Ptr3 configured tofeedback the electric power of the ejection head 50 are also provided,the output terminal of the operational amplifier Opamp is also connectedto the gate electrodes of the transistors Ptr0 to Ptr3, and switches SP0to SP3 are provided between the respective gate electrodes and theoutput terminal of the operational amplifier Opamp. In the respectivetransistors Ptr0 to Ptr3, the gate electrodes are applied with thepull-up process for avoiding erroneous operation. However, in order toavoid complication of drawing, it is not shown in the drawing.

The gate selector circuit 140 switches the states of the switches SN1 toSN4 and the switches SP0 to SP3 ON or OFF. Then, depending on which oneof the switches SN1 to SN4 or the switches SP0 to SP3 are turned on, thenegative feedback circuit is formed by the corresponding transistorsNtr1 to Ntr4 or the transistors Ptr0 to Ptr3, and the operationalamplifier Opamp. Consequently, the voltage value applied to the ejectionhead 50 can be negative feedback controlled by causing the same tofollow the analogue voltage outputted from the DAC. This point will bedescribed in detail below.

C-2. Operation of Ejection Head Driving Circuit

FIGS. 9A and 9B are explanatory drawings showing an operation of theejection head driving circuit 100 according to the second embodimentwhich drives the ejection head 50. In the second embodiment as well, thepower sources E1, E2, E3, E4 generate the electric powers having thevoltage values of E1, E2, E3, E4, and the respective voltage values havea relationship; 0 (V)<E1<E2<E3<E4. In order to avoid complicateddescription, the internal resistances of the respective transistors Ntr1to Ntr4, Ptr0 to Ptr3 or the diodes are assumed to be ignorable in thesecond embodiment as well.

In a case where the driving voltages to be applied to the ejection head50 (the analogue voltage outputted from the DAC) is increased, theejection head driving circuit 100 in the second embodiment operates inthe completely same manner as the first embodiment described above inconjunction with FIG. 4A to FIG. 4C. In other words, when the drivingvoltage is in the voltage range from 0 (V) to E1, the gate selectorcircuit 140 turns the switch SN1 ON and turns all other switches(switches SN2 to SN4, and switches SP0 to SP3) OFF. Consequently, anegative feedback circuit by the transistor Ntr1 and the operationalamplifier Opamp is formed and the electric power of the power source E1is applied to the ejection head 50 according to the analogue voltageoutputted from the DAC. Also, when the driving voltage to be applied tothe ejection head 50 exceeds the maximum possible voltage value to besupplied from the power source E1, the switch SN1 is turned OFF and theswitch SN2 is turned ON. Consequently, the negative feedback circuitformed by the transistor Ntr1 and the operational amplifier Opamp isswitched to the negative feedback circuit by the transistor Ntr2 and theoperational amplifier Opamp, and then the electric power of the powersource E2 is supplied to the ejection head 50.

FIG. 9B shows a state in which the electric power is supplied from thepower source E1 to the ejection head 50 via the transistor Ntr1 whilethe driving voltage rises from 0 (V) to E1, and the electric power issupplied from the power source E2 to the ejection head 50 via thetransistor Ntr2 while the driving voltage rises from E1 to E2. In thismanner, while the driving voltage to be applied to the ejection head 50rises, the power sources which supply the electric power to the ejectionhead 50 may be switched in sequence by switching the switches SN1 toSN4.

In contrast, when the driving voltage to be applied to the ejection head50 (the analogue voltage outputted from the DAC) is decreased, all theswitches SN1 to SN4 are turned OFF and one of the switches SP0 to SP3 isturned ON according to the driving voltage. For example, a case wherethe driving voltage is decreased from E2 to E1 will be considered. Whenthe driving voltage is within the range from E1 to E2, and reduction iswanted, the switch SP1 is turned ON. Then, the output of the operationalamplifier Opamp is inputted to the gate electrode of the transistorPtr1, and a channel of a positive hole is formed in the transistor Ptr1,so that the ejection head 50 and the power source E1 are electricallyconnected. Since the voltage value E2 is applied to the ejection head50, the electric power stored in the ejection head 50 is fed back to thepower source E1. Then, when the power source E1 is a power source whichis able to store the electric power supplied from the outside, forexample, such as the secondary battery, the stored electric power can beused for driving the ejection head 50, so that the power consumption issignificantly reduced.

The transistor Ptr1 has a feature such that if the voltage to be appliedto the gate electrode is lowered, the equivalent value of resistance ofthe transistor Ptr1 becomes smaller correspondingly. Therefore, byinputting the analogue voltage outputted from the DAC (a target voltageto be applied to the ejection head 50) and the driving voltage actuallyapplied to the ejection head 50 to the operational amplifier Opamp andapplying the output from the operational amplifier Opamp to the gateelectrode, the negative feedback circuit is formed and the drivingvoltage applied to the ejection head 50 can be controlled. For example,when the driving voltage applied to the ejection head 50 is higher thanthe target voltage outputted from the DAC, the output from theoperational amplifier Opamp is decreased, and hence the equivalent valueof resistance of the transistor Ptr1 is also decreased. Consequently,the driving voltage applied to the ejection head 50 is decreased andgets close to the target voltage outputted from the DAC.

In FIG. 9A, the negative feedback circuit formed by the transistor Ptr1and the operational amplifier Opamp when the switch SP1 is turned ON isindicated by the thick solid line. In this manner, when the drivingvoltage of the ejection head 50 is decreased from the voltage value E2to the voltage value E1 while performing the negative feedback control,the electric power stored in the ejection head 50 is fed back to thepower source E1 via the transistor Ptr1 and, as a consequence, thedriving voltage is gradually decreased. FIG. 9B shows a state in whichthe electric power of the ejection head 50 is fed back to the powersource E1 via the transistor Ptr1 by a thick solid arrow.

When the driving voltage of the ejection head 50 is decreased to a levellower than the voltage value E1, the switch SP1 is turned OFF and theswitch SP0 is turned ON using the gate selector circuit 140.Consequently, the negative feedback circuit formed by the transistorPtr1 and the operational amplifier Opamp (the circuit indicated by thethick solid line in FIG. 9A) is switched to a new negative feedbackcircuit formed by the transistor Ptr0 and the operational amplifierOpamp. In FIG. 9A, the newly switched negative feedback circuit is shownby the thick broken line. Consequently, the electric power stored in theejection head 50 is discharged to a ground via the transistor Ptr0 and,in association with this, the driving voltage applied to the ejectionhead 50 is lowered. FIG. 9B shows a state in which the electric power ofthe ejection head 50 is discharged to the ground via the transistor Ptr0by a thick broken arrow. Also, when raising the driving voltage againfrom the decreased state, the switch corresponding to the currentvoltage value from among the switches SN1 to SN4 may be turned ON asdescribed above.

In this manner, in the ejection head driving circuit 100 in the secondembodiment as well, the voltage range which can be applied to theejection head 50 is divided into four voltage ranges of 0 (V) to E1, E1to E2, E2 to E3, and E3 to E4, and the power sources E1 to E4 which areassigned to their own voltage ranges respectively are set in advance.Then, when raising the driving voltage to be applied to the ejectionhead 50, the power source which is assigned to the corresponding voltagerange is connected to the ejection head 50, and the driving voltage isapplied to the ejection head 50 while performing the negative feedbackcontrol. For example, when the driving voltage is in between the voltagevalue E1 and the voltage value E2, the power source E2 which is assignedto the voltage range of E1 to E2 is used to drive the ejection head 50.In contrast, when reducing the driving voltage to be applied to theejection head 50, the power source which is assigned to the voltagerange which is one level lower than the current voltage is connected tothe ejection head 50.

Then, the negative feedback control is performed while feeding back theelectric power stored in the ejection head 50 to the power source, sothat the driving voltage to be applied to the ejection head 50 isdecreased. For example, when the driving voltage is in between thevoltage value E1 and the voltage value E2, the power source E1 which isassigned to the voltage range of 0 (V) to E1 is connected to theejection head 50, and the electric power of the ejection head 50 isstored in the power source E1. Accordingly, the power consumption whendriving the ejection head 50 can be reduced. In particular, when thepower sources E1 to E4 are the power sources which are able to store atleast part of the electric power supplied from the outside as thesecondary battery or the capacitor, the power consumption can further bereduced. The reason will be described below.

FIG. 10A and FIG. 10B are explanatory drawings showing a state in whichthe driving voltage to be applied to the ejection head 50 is raised from0(V) to E4 and then is decreased from E4 to 0(V) in the ejection headdriving circuit 100 according to the second embodiment. FIG. 10A shows astate in which the electric power is supplied from the power source unit10 to the ejection head 50 or the electric power is recovered from theejection head 50 to the power source unit 10 in association with theincrease and decrease of the driving voltage. FIG. 10B shows a state inwhich the switches SN1 to SN4, and the switches SP0 to SP3 are switchedto ON or OFF in association with the increase or decrease of the drivingvoltage.

As shown in FIG. 10B, when raising the driving voltage from 0(V) to E1,the driving voltage is raised while supplying the electric power of thepower source E1 to the ejection head 50 via the transistor Ntr1 byturning the switch SN1 ON. When the driving voltage reaches the voltagevalue E1, the switch SN1 is turned OFF and the switch SN2 is turned ON,so that the driving voltage is raised while supplying the electric powerof the power source E2 to the ejection head 50 via the transistor Ntr2.When the driving voltage reaches the voltage value E2, the switch SN2 isturned OFF and the switch SN3 is turned ON, so that the electric powerof the power source E3 is supplied to the ejection head 50 via thetransistor Ntr3.

Furthermore, when the driving voltage reaches the voltage value E3, theswitch SN3 is turned OFF and the switch SN4 is turned ON, so that theelectric power of the power source E4 is supplied to the ejection head50 via the transistor Ntr4. FIG. 10A and FIG. 10B show a state in whichthe driving voltage to be applied to the ejection head 50 is graduallyraised while switching the power sources E1 to E4 in this manner. Asshown in FIG. 10A, during this period, the electric powers are suppliedfrom the power sources E1, E2, E3, E4 to the ejection head 50 via thetransistors Ntr1 to Ntr4. At this time, the voltage differences inoperation of the respective transistors Ntr1 to Ntr4 are only thevoltage differences generated by the respective power sources E1 to E4,that is, the voltage differences of about 0 (V) to E1, E1 to E2, E2 toE3, and E3 to E4 at the most. Therefore, in the same manner as theejection head driving circuit 100 according to the first embodiment, thepower consumption is reduced by the effect of reducing the operationalpotential difference.

Subsequently, when reducing the driving voltage from the voltage valueE4, the switch SN4 is firstly turned OFF, and then the switch SP3 isturned ON. Then, as described above, the electric power stored in theejection head 50 is fed back to the power source E3 via the transistorPtr3 and, in association with this, the driving voltage applied to theejection head 50 is decreased. If the power source E3 is a power sourcewhich is able to store the supplied electric power in this case, theelectric power fed back from the ejection head 50 is recovered andstored in the power source E3.

When the driving voltage of the ejection head 50 is decreased to thevoltage value E3, the switch SP3 is turned OFF and the switch SP2 isturned ON, so that the electric power of the ejection head 50 is fedback to the power source E2 via the transistor Ptr2. Consequently, theelectric power recovered from the ejection head 50 is now stored in thepower source E2. Furthermore, when the driving voltage is decreased tothe voltage value E2, the switch SP2 is turned OFF and the switch SP1 isturned ON to feed back the electric power of the ejection head 50 to thepower source E1 via the transistor Ptr1. If the power source E2 or thepower source E1 is able to store the electric power, the electric powerfed back from the ejection head 50 is stored in the power source E2 orthe power source E1. When the driving voltage is decreased to thevoltage value E1, finally, the switch SP1 is turned OFF and the switchSP0 is turned ON. Then, the electric power of the ejection head 50 isdischarged to the ground via the transistor Ptr0 and, in associationwith it, the driving voltage applied to the ejection head 50 isdecreased to 0(V).

FIG. 10A and FIG. 10B show a state in which the driving voltage appliedto the ejection head 50 is gradually decreased while feeding back thedriving voltage applied to the ejection head 50 to the power sourceswhich generate electric powers having lower voltage values. In theejection head driving circuit 100 according to the second embodiment,the power sources which are able to store the electric power suppliedfrom the outside such as the secondary battery are used as the powersources E1 to E3 to which the electric powers are fed back from theejection head 50. The arrows indicated by thick solid lines in FIG. 10Aand FIG. 10B show a state in which the driving voltage is decreasedwhile storing the electric powers fed back from the ejection head 50 inthe power sources E1 to E3.

In this manner by recovering the electric power from the ejection head50 and storing the same in the power source when reducing the drivingvoltage, the stored electric power can be used for raising the drivingvoltage for the next time. For example, when the driving voltage israised from 0 (V) to E1 again, the electric power is supplied from thepower source E1. At this time, by supplying the electric power recoveredfrom the ejection head 50 and stored therein, a new electric power doesnot practically have to be supplied and the driving voltage of theejection head 50 can be raised.

In the same manner, since the electric power from the ejection head 50is recovered and stored in the power source E2 and the power source E3as well, when raising the driving voltage from E1 to E2, and furtherfrom E2 to E3, a new electric power does not practically have to besupplied by supplying only the electric powers stored in the powersource E2 and the power source E3 to the ejection head 50, so that thedriving voltage to be applied to the ejection head 50 can be raised.After all, by storing the electric power recovered from the ejectionhead 50 in the power sources, the driving voltage in the range from 0(V) to E3 can be applied without supplying the new electric power and,consequently, the power consumption can be reduced significantly.

In the description given above, the four power sources; the powersources E1 to E4 are provided in the ejection head driving circuit 100.However, by providing a larger number of power sources and dividing thevoltage range to be applied to the ejection head 50 more finely, therange of the driving voltage which can be applied to the ejection head50 without supplying the new electric power can be enlarged.Consequently, the power consumption can be reduced furthersignificantly. In the ejection head driving circuit 100 according to thesecond embodiment as well, application of the negative driving voltageor application of the driving voltage which changes between the positivevalues and the negative values can be achieved to the ejection head 50as in the first embodiment.

D. Modified Embodiment

In addition to the embodiments described above, there are otherconceivable modified embodiments. These modified embodiments will bedescribed below.

D-1. First Modified Embodiment

In the second embodiment described above, the power sources E1 to E4which generate voltages higher than the voltage value applied to theejection head 50 are connected to the ejection head 50 while the drivingvoltage is increasing, and the power sources E1 to E4 which generatevoltages lower than the voltage value applied to the ejection head 50are connected to the ejection head 50 while the driving voltage isreducing. Therefore, as shown in FIG. 10B, only one of the respectiveswitches of SN1 to SN4 and SP0 to Sp3 are turned ON. In contrast, it isalso possible to drive the ejection head 50 while connecting a powersource unit which generates a higher voltage value and a power sourceunit which generates a lower voltage value than that applied to theejection head 50 simultaneously.

FIGS. 11A to FIG. 11C are explanatory drawings showing a state ofdriving the ejection head 50 in the ejection head driving circuit 100according to a first modified embodiment as described above. FIG. 11Ashows a state in which the driving voltage is applied to the ejectionhead 50 while switching the negative feedback circuits of the powersources E1 to E4. In FIG. 11B, the setting state of the respectiveswitches; SN1 to SN4, and SP0 to SP3 at this time is shown. As shown inFIG. 11B, in the ejection head driving circuit 100 according to thefirst modified embodiment, the negative feedback circuit of the powersource unit which generates a voltage higher than the voltage value tobe applied to the ejection head 50 and the negative feedback circuit ofthe power source unit which generates a voltage lower than that arealways in ON state.

As shown in FIG. 11C, the voltage value applied to the ejection head 50does not necessarily match the voltage value of the target voltagewaveform always completely, and is normally controlled while becominghigher or lower than the target voltage waveform. Here, in the ejectionhead driving circuit 100 according to the first modified embodiment,when the applied voltage exceeds the target voltage in the course ofincreasing the target voltage to be applied to the ejection head 50, theelectric power is recovered by the power source unit which generates alow voltage value, so that the applied voltage can be brought closer tothe target voltage quickly.

In contrast, when the applied voltage underruns the target voltage inthe course of decreasing the target voltage to be applied to theejection head 50, the electric power is supplied from the power sourceunit which generates a high voltage value, so that the applied voltagecan be brought closer to the target voltage quickly. In this manner, inthe ejection head driving circuit 100 according to the first modifiedembodiment, even when an overshooting of the applied voltage occurswhile increasing the target voltage or, in contrast, even when anundershooting of the applied voltage occurs while decreasing the targetvoltage, the applied voltage can be brought closer to the target voltagequickly, so that an accurate driving voltage waveform can be supplied tothe ejection head 50.

The timings of switching the respective switches of SN1 to SN4, SP0 toSP3 are timings when the driving voltage reaches the voltage valuesgenerated by the respective power source units E1 to E4. In fact,however, the voltage drop occurs by an amount of internal resistances ofthese switches and the transistors. Therefore, as regards the switchesSN1 to SN4 on the side which supplies the electric power from the powersource unit to the ejection head 50, switching at a timing a littlebefore the driving voltage reaches the voltage value generated by thepower source unit is preferable. In contrast, as regards the switchesSP0 to SP3 on the side which recovers the electric power from theejection head 50 to the power source unit, switching at a timing alittle after the driving voltage reaches the voltage value generated bythe power source unit is preferable. In FIG. 11B, considering the thingsas described above, the timing of switching the switches SN1 to SN4 andthe timing of switching the switches SP0 to SP3 are shifted a little.

D-2. Second Modified Embodiment

In the embodiments described above, the description is given on thebasis of an assumption that all of the power sources E1 to E4 generatethe electric powers having the always stable voltage values. However,there exist power sources whose voltage value is lowered as it suppliesthe electric power like the capacitor and power sources which do notnecessarily generate the electric power having the stable voltage valuelike the secondary battery. In addition, there may be a case where thesupply of the electric power having a stable voltage value is difficultbecause the electric power supplied to the ejection head 50 is excessivewith respect to the capacity of the power source. In such a case, it isalso possible to observe the voltage values which the respective powersources generate, and switch the switches SN1 to SN4 or the switches SP0to SP3 so that the power source which generates an optimum voltage valueis connected to the ejection head 50 according to the driving voltage tobe applied to the ejection head 50.

FIG. 12 is an explanatory drawing illustrating an example of theejection head driving circuit 100 according to a second modifiedembodiment as described above. In the ejection head driving circuit 100shown in FIG. 12, the voltage values generated by the power sources E1to E4, and the driving voltage to be applied to the ejection head 50(the output voltage from the DAC) are inputted to the gate selectorcircuit 140. Then, the gate selector circuit 140 switches the switchesSN1 to SN4 or the switches SP0 to SP3 according to the determinationwhether the driving voltage is rising or decreasing, and to the drivingvoltage values and the voltage values generated by the respective powersources.

For example, if the driving voltage is rising, the corresponding switchfrom the switches SN1 to SN4 is turned ON so that the electric power issupplied to the ejection head 50 from the power source having the lowestvoltage value from among the power sources which generate voltage valueshigher than the driving voltage by a certain extent. In contrast, if thedriving voltage is decreasing, the corresponding switch from theswitches SP0 to SP3 is turned ON so that the electric power is recoveredfrom the ejection head 50 to the power source having the highest voltagevalue from among the power sources which generate voltage values lowerthan the driving voltage by a certain extent. In this configuration,even though the voltage values generated by the respective power sourcesare not stable, application of the adequate driving voltage to theejection head 50 is achieved while reducing the power consumption.

D-3. Third Modified Embodiment

In the embodiments described above, the description is given on thebasis of the assumption that the driving voltage to be applied to theejection head 50 is inputted as is to the operational amplifier Opamp toperform the negative feedback control. However, the driving voltage maybe inputted to the operational amplifier Opamp after having divided onceinstead of inputting the same directly to the operational amplifierOpamp.

FIG. 13 is an explanatory drawing illustrating an example of theejection head driving circuit 100 according to a third modifiedembodiment as described above. In the ejection head driving circuit 100shown in FIG. 13, the driving voltage applied to the ejection head 50 isinputted to the operational amplifier Opamp after having divided into1/n by a voltage dividing circuit using resistance. In thisconfiguration, the voltage that the DAC generates may be 1/n of thedriving voltage to be applied to the ejection head 50. Therefore,control of the driving voltage having a large amount of fluctuations isenabled using the DAC having a small output range.

D-4. Fourth Modified Embodiment

In the embodiments and the modified embodiments described above, thediodes for preventing the reverse flow are inserted between thetransistors and the ejection head 50 in order to avoid the parasiticdiode in the transistor from being biased forwardly and causing thereverse flow of the electric current. Therefore, the voltage drop andthe power loss are generated by the internal resistances of the diodesfor preventing the reverse flow. However, by connecting the NMOS-typetransistors and the PMOS-type transistors in series, the diodes forpreventing the reverse flow can be omitted.

FIG. 14A and FIG. 14B are explanatory drawings illustrating the ejectionhead driving circuit 100 according to a fourth modified embodiment inwhich the NMOS-type transistors and the PMOS-type transistors areconnected in series. FIG. 14A shows a circuit diagram in which theNMOS-type transistor and the PMOS-type transistor are connected inseries, and FIG. 14B shows a state in which the respective transistorsare operated according to the operating state of the ejection headdriving circuit 100. In FIG. 14B, the parasitic diodes of the respectivetransistors are also illustrated.

In this manner, by connecting the NMOS-type transistors and thePMOS-type transistors in series, and switching the operating state ofthe respective transistors, loading of the electric power to theejection head 50 or recovering of the electric power from the ejectionhead 50 are enabled. For example, when the ejection head driving circuit100 is not operated, both the NMOS-type transistor and the PMOS-typetransistor may be used as switching elements and switched to an OFFstate. The NMOS-type transistor and the PMOS-type transistor are formedwith the parasitic diodes respectively. However, since the directions ofthe parasitic diodes are directed in the opposite direction, theelectric current does not flow reversely as long as the respectivetransistors are in the OFF state.

When the electric power is loaded from the power source unit to theejection head 50, the transistors connected to a power source unit En+1on the high-voltage side of the voltage applied to the ejection head 50and a power source unit En on the low-voltage side respectively areoperated as follows. First of all, the NMOS-type transistor on thehigh-voltage side is functioned as the switching element and is set tothe ON state, while the PMOS-type transistor is functioned as anamplifier element to perform the negative feedback control. On thelow-voltage side, both the NMOS-type transistor and the PMOS-typetransistor are functioned as the switching element and are set to theOFF state.

In contrast, when recovering the electric power from the ejection head50 to the power source unit, on the high-voltage side with respect tothe voltage value of the ejection head 50, both the NMOS-type transistorand the PMOS-type transistor are functioned as the switching element andare set to the OFF state. On the low-voltage side, the PMOS-typetransistor is functioned as the switching element and is set to the ONstate, while the NMOS-type transistor is functioned as the amplifierelement to perform the negative feedback control.

In this manner, by connecting the NMOS-type transistors and thePMOS-type transistors in series, and switching the operating state ofthe respective transistors, loading of the electric power to theejection head 50 or recovering of the electric power from the ejectionhead 50 are enabled. Since the diodes for preventing the reverse floware not necessary to be inserted, so that the occurrence of the voltagedrop or the power loss due to the internal resistance of the diode canbe avoided.

As described above, the invention is not limited to a configuration inwhich the NMOS-type transistors and the PMOS-type transistors areconnected in series, and a configuration in which the two NMOS-typetransistors (or PMOS-type transistors) are connected in series is alsoapplicable as a matter of course. In such a case, the transistors may beconnected in series with the respective parasitic diodes directedopposite from each other.

D-5. Fifth Modified Embodiment

In the fourth modified embodiment described above, a floating drive isnecessary for at least the gate electrode of the transistor on the sideof the ejection head 50 from between the NMOS-type transistor and thePMOS-type transistor connected in series, and a power source specificfor the floating drive is additionally needed. However, as shown in FIG.15, by separating a substrate of the MOS-type transistor from the sourceelectrode and connecting the same to the power source or the ground, thefloating drive is not necessary. In this configuration, since theparasitic diode is not formed in the transistor, insertion of the diodefor preventing the reverse flow is not necessary.

D-6. Sixth Modified Embodiment

Although the plurality of ejection nozzles are provided in the ejectionhead 50, these ejection nozzles are not constantly driven, and thenumber of ejection nozzles to be driven simultaneously fluctuatessignificantly according to the image to be printed. When the number ofthe ejection nozzle fluctuates significantly, the ejection head drivingcircuit 100 which drives the ejection head 50 is also affected, so thatthe stable generation of the driving voltage waveform is difficult. Inview of such points, a dummy load may be connected in parallel to theejection head 50.

FIG. 16 is an explanatory drawing illustrating an example of theejection head driving circuit 100 according to a sixth modifiedembodiment in which a dummy load 55 is connected to the ejection head 50in parallel. As illustrated, by connecting the dummy load 55 in parallelto the ejection head 50, even when the number of the ejection nozzles tobe driven fluctuates significantly, the effect on the ejection headdriving circuit 100 can be reduced. For example, by setting themagnitude of the load of the dummy load 55 to be substantially the sameas the ejection head 50, even when the ejection nozzles drivensimultaneously fluctuates between the all nozzles and no nozzle, theratio of coefficient of fluctuation of the load becomes a half when itis considered as the entire load including the ejection head 50 and thedummy load 55. Therefore, since the effect on the ejection head drivingcircuit 100 is decreased, and hence the ejection head 50 can be drivenwith the stable driving voltage waveform.

Although the various types of ejection head driving circuit have beendescried, the invention is not limited to all of the embodimentsdescribed above, and various modes may be employed without departingfrom the scope of the invention.

What is claimed is:
 1. An ejection head driving circuit configured tosupply a driving voltage waveform to an ejection head provided withejection nozzles for ejecting fluid, the circuit comprising: a targetvoltage waveform output unit configured to output a target voltagewaveform supply to the ejection head; a plurality of power source unitsconfigured to generate electric powers having different voltage values;a plurality of negative feedback control units configured to supply theelectric powers from the respective power source units to the ejectionhead and perform negative feedbacks on the voltage values so as to matchthe voltage value applied to the ejection head with that of the targetvoltage waveform; and a power source connecting unit configured toselect and connect one of the plurality of power source units to theejection head based on the applied voltage value or the voltage value ofthe target voltage waveform, and disconnect the other power source unitsfrom the ejection head, wherein the power source units are capable ofstoring electric power supplied from an external power source; the powersource connecting unit selects a first power source unit and a secondpower source unit, the first power source unit generating a highervoltage value than the voltage value applied to the ejection head or thevoltage value of the target voltage waveform, the second power sourceunit generating a lower voltage value than the voltage value applied tothe ejection head or the voltage value of the target voltage waveform;the power source connecting unit connects the first power source unit tothe ejection head when the voltage value applied to the ejection head islower than the voltage value of the target voltage waveform, andconnects the second power source unit to the ejection head when thevoltage value applied to the ejection head is higher than the voltagevalue of the target voltage waveform; and a load connected in parallelto the ejection head and capable of storing electric power supplied froman external power source; wherein the power source units are capable ofstoring electric power supplied from an external source; and the powersource connecting unit connects the selected power source unit to theejecting head and the load.
 2. A fluid jet printing apparatus comprisingthe ejection head driving circuit according to claim
 1. 3. A method ofdriving an ejection head by supplying a driving voltage waveform to anejection head provided with ejection nozzles to eject fluid, the methodcomprising: outputting a target voltage waveform to be supplied to theejection head, the target voltage waveform including a voltageincreasing portion in which a voltage value increases as time elapses, avoltage maintaining portion in which the voltage value stays, and avoltage decreasing portion in which the voltage value decreases as timeelapses; generating electric powers of different voltage values from aplurality of power source units; selecting one of the plurality of powersource units on the basis of the voltage value applied to the ejectionhead or the voltage value of the target voltage waveform; and performinga negative feedback on the voltage value received from the selectedpower source unit so as to match the voltage value applied to theejection head with that of the target voltage waveform, wherein thepower source units are capable of storing electric power supplied froman external power source; the power source connecting unit is selectedfrom a first power source unit and a second power source unit, the firstpower source unit generating a higher voltage value than the voltagevalue applied to the ejection head or the voltage value of the targetvoltage waveform, the second power source unit generating a lowervoltage value than the voltage value applied to the ejection head or thevoltage value of the target voltage waveform; and the first power sourceunit is connected to the ejection head when the voltage value applied tothe ejection head is lower than the voltage value of the target voltagewaveform, and the second power source unit is connected to the ejectionhead when the voltage value applied to the ejection head is higher thanthe voltage value of the target voltage waveform.